source: trunk/LMDZ.TITAN.old/libf/phytitan/write_histday.h @ 3094

Last change on this file since 3094 was 1572, checked in by emillour, 8 years ago

All GCMs:
Further adaptations to keep up with changes in LMDZ5 concerning
physics/dynamics separation (up to rev r2500 of LMDZ5)

  • arch:
  • remove ifort debug option '-check all', replace it with '-check bounds,format,output_conversion,pointers,uninit' (i.e. get it to stop complaining about copying into temporary arrays)
  • dyn3d_common:
  • comconst_mod.F90 : add ngroup
  • dyn3d:
  • gcm.F90 : minor bug fix (arguments to a call_abort())
  • leapfrog.F90 : recompute geopotential for bilan_dyn outputs
  • conf_gcm.F90 : read "ngroup" from run.def
  • groupe.F , groupeun.F : ngroup no longer a local parameter
  • dyn3d_par:
  • conf_gcm.F90 : read "ngroup" from run.def
  • groupe_p.F , groupeun_p.F : ngroup no longer a local parameter
  • misc:
  • regr1_step_av_m.F90 : removed (not used)
  • phy_common:
  • mod_phys_lmdz_mpi_transfert.F90 , mod_phys_lmdz_mpi_data.F90 : change is_north_pole and is_south_pole to is_north_pole_dyn and is_south_pole_dyn
  • mod_phys_lmdz_omp_data.F90 : introduce is_nort_pole_phy and is_south_pole_phy
  • dynphy_lonlat:
  • mod_interface_dyn_phys.F90 : use is_north_pole_dyn and is_south_pole_dyn
  • calfis_p.F : use is_north_pole_dyn and is_south_pole_dyn
  • phyvenus:
  • physiq_mod , write_hist*.h : use is_north_pole_phy and is_south_pole_phy to correctly compute mesh area at poles to send to hist*nc files.
  • phytitan:
  • physiq_mod , write_hist*.h : use is_north_pole_phy and is_south_pole_phy to correctly compute mesh area at poles to send to hist*nc files.

EM

File size: 11.3 KB
Line 
1!
2! $Header: /home/cvsroot/LMDZ4/libf/phylmd/write_histday.h,v 1.2 2004/06/01 09:27:10 lmdzadmin Exp $
3!
4      IF (ok_journe) THEN
5
6         zsto = dtime
7         zout = dtime * REAL(ecrit_day)
8         itau_w = itau_phy + itap
9
10c-------------------------------------------------------
11      IF(lev_histday.GE.1) THEN
12
13ccccccccccccc 2D fields, invariables
14
15      call histwrite_phy(nid_day,.false.,"phis",itau_w,pphis)
16c      call histwrite_phy(nid_day,.false.,"aire",itau_w,cell_area)
17      cell_area_out(:)=cell_area(:)
18      if (is_north_pole_phy) cell_area_out(1)=cell_area(1)/nbp_lon
19      if (is_south_pole_phy) cell_area_out(klon)=cell_area(klon)/nbp_lon
20      call histwrite_phy(nid_day,.false.,"aire",itau_w,cell_area_out)
21
22ccccccc axe Ls ... Faudrait le reduire a axe temporel seulement...
23c Correction passage de 360 a 0... Sinon probleme avec moyenne
24      if (zls.lt.zlsm1) then
25        do i=1,klon
26          tmpout(i,1) = zls*180./RPI+360.
27        enddo
28        zlsm1 = 2.*RPI
29      else
30        do i=1,klon
31          tmpout(i,1) = zls*180./RPI
32        enddo
33        zlsm1 = zls
34      endif
35      call histwrite_phy(nid_day,.false.,"ls",itau_w,tmpout(:,1))
36
37ccccccccccccc 2D fields, variables
38
39      call histwrite_phy(nid_day,.false.,"tsol",itau_w,ftsol)
40      call histwrite_phy(nid_day,.false.,"psol",itau_w,paprs(:,1))
41
42c     call histwrite_phy(nid_day,.false.,"ue",itau_w,ue)
43c     call histwrite_phy(nid_day,.false.,"ve",itau_w,ve)
44
45      ENDIF !lev_histday.GE.1
46
47c-------------------------------------------------------
48      IF(lev_histday.GE.2) THEN
49
50ccccccccccccc 3D fields, basics
51
52      call histwrite_phy(nid_day,.false.,"temp",itau_w,t_seri)
53      call histwrite_phy(nid_day,.false.,"pres",itau_w,pplay)
54      call histwrite_phy(nid_day,.false.,"geop",itau_w,zphi)
55      call histwrite_phy(nid_day,.false.,"vitu",itau_w,u_seri)
56      call histwrite_phy(nid_day,.false.,"vitv",itau_w,v_seri)
57      call histwrite_phy(nid_day,.false.,"vitw",itau_w,omega)
58      call histwrite_phy(nid_day,.false.,"tops",itau_w,topsw)
59      call histwrite_phy(nid_day,.false.,"duvdf",itau_w,d_u_vdf)
60      call histwrite_phy(nid_day,.false.,"dudyn",itau_w,d_u_dyn)
61
62cccccccccccccccccc  Tracers
63
64         if (iflag_trac.eq.1) THEN
65          if (microfi.ge.1) then
66c          DO iq=1,nmicro
67c      call histwrite_phy(nid_day,.false.,tname(iq),
68c    .                    itau_w,qaer(1:klon,1:klev,iq))
69c          ENDDO
70c    -------   NB AER TOT
71               do i=1,klon
72                 do j=1,klev
73                   tmpout(i,j)= SUM(qaer(i,j,1:nrad))
74                 enddo
75               enddo
76       call histwrite_phy(nid_day,.false.,"qaer",itau_w,tmpout)
77
78             if (clouds.eq.1) then
79c    -------   NB NOY TOT
80               do i=1,klon
81                 do j=1,klev
82                   tmpout(i,j)= SUM(qaer(i,j,nrad+1:2*nrad))
83                 enddo
84               enddo
85       call histwrite_phy(nid_day,.false.,"qnoy",itau_w,tmpout)
86c    -------   V GLA1 TOT
87               do i=1,klon
88                 do j=1,klev
89                   tmpout(i,j)= SUM(qaer(i,j,2*nrad+1:3*nrad))
90                 enddo
91               enddo
92       call histwrite_phy(nid_day,.false.,"qgl1",itau_w,tmpout)
93c    -------   V GLA2 TOT
94               do i=1,klon
95                 do j=1,klev
96                   tmpout(i,j)= SUM(qaer(i,j,3*nrad+1:4*nrad))
97                 enddo
98               enddo
99       call histwrite_phy(nid_day,.false.,"qgl2",itau_w,tmpout)
100c    -------   V GLA3 TOT
101               do i=1,klon
102                 do j=1,klev
103                   tmpout(i,j)= SUM(qaer(i,j,4*nrad+1:5*nrad))
104                 enddo
105               enddo
106       call histwrite_phy(nid_day,.false.,"qgl3",itau_w,tmpout)
107c --------------
108c ----- SATURATION ESP NUAGES
109       call histwrite_phy(nid_day,.false.,"ch4sat",itau_w,satch4)
110       call histwrite_phy(nid_day,.false.,"c2h6sat",itau_w,satc2h6)
111       call histwrite_phy(nid_day,.false.,"c2h2sat",itau_w,satc2h2)
112c --------------
113c ----- RESERVOIR DE SURFACE
114       call histwrite_phy(nid_day,.false.,"reserv",itau_w,reservoir)
115c --------------
116c ----- ECHANGE GAZ SURF/ATM (evaporation)
117       call histwrite_phy(nid_day,.false.,"evapch4",itau_w,evapch4)
118c --------------
119c ----- PRECIPITATIONS
120c       -----  CH4
121       call histwrite_phy(nid_day,.false.,"prech4",
122     .            itau_w,precip(1:klon,1))
123c       -----  C2H6
124       call histwrite_phy(nid_day,.false.,"prec2h6",
125     .            itau_w,precip(1:klon,2))
126c       -----  C2H2
127       call histwrite_phy(nid_day,.false.,"prec2h2",
128     .            itau_w,precip(1:klon,3))
129c       -----  NOY
130       call histwrite_phy(nid_day,.false.,"prenoy",
131     .            itau_w,precip(1:klon,4))
132c       -----  AER
133       call histwrite_phy(nid_day,.false.,"preaer",
134     .            itau_w,precip(1:klon,5))
135c --------------
136c ----- FLUX GLACE
137c       -----  CH4
138       call histwrite_phy(nid_day,.false.,"flxgl1",
139     .            itau_w,flxesp_i(1:klon,1:klev,1))
140c       -----  C2H6
141       call histwrite_phy(nid_day,.false.,"flxgl2",
142     .            itau_w,flxesp_i(1:klon,1:klev,2))
143c       -----  C2H2
144       call histwrite_phy(nid_day,.false.,"flxgl3",
145     .            itau_w,flxesp_i(1:klon,1:klev,3))
146c --------------
147c ----- Source/puits GLACE
148c       -----  CH4
149       call histwrite_phy(nid_day,.false.,"solch4",
150     .            itau_w,solesp(1:klon,1:klev,1))
151c       -----  C2H6
152       call histwrite_phy(nid_day,.false.,"solc2h6",
153     .            itau_w,solesp(1:klon,1:klev,2))
154c       -----  C2H2
155       call histwrite_phy(nid_day,.false.,"solc2h2",
156     .            itau_w,solesp(1:klon,1:klev,3))
157c --------------
158c ----- RAYON MOYEN GOUTTE
159       call histwrite_phy(nid_day,.false.,"rcldbar",itau_w,rmcloud)
160
161             endif
162          endif
163
164c --------------
165c ----- TRACEURS CHIMIQUES
166          if (nmicro.lt.nqmax) then
167           DO iq=nmicro+1,nqmax
168       call histwrite_phy(nid_day,.false.,tname(iq),
169     .                    itau_w,tr_seri(1:klon,1:klev,iq))
170           ENDDO
171          endif
172         endif
173
174      ENDIF !lev_histday.GE.2
175
176c-------------------------------------------------------
177      IF(lev_histday.GE.3) THEN
178
179cccccccccccccccccc  Radiative transfer
180
181c 2D
182
183      call histwrite_phy(nid_day,.false.,"topl",itau_w,toplw)
184      call histwrite_phy(nid_day,.false.,"sols",itau_w,solsw)
185      call histwrite_phy(nid_day,.false.,"soll",itau_w,sollw)
186
187c 3D
188
189      call histwrite_phy(nid_day,.false.,"SWnet",
190     .          itau_w,swnet(1:klon,1:klev))
191      call histwrite_phy(nid_day,.false.,"LWnet",
192     .          itau_w,lwnet(1:klon,1:klev))
193
194c --------------
195c ----- OPACITE BRUME
196       do k=7,NSPECV,10
197         do i=1,klon
198         do l=1,klev
199           t_tauhvd(i,l)=TAUHVD(i,klev-l+1,k)
200         enddo
201         enddo
202         write(str2,'(i2.2)') k
203       call histwrite_phy(nid_day,.false.,"thv"//str2,itau_w,t_tauhvd)
204       enddo      ! fin boucle NSPECV
205
206       do k=8,NSPECI,10
207         do i=1,klon
208         do l=1,klev
209           t_tauhvd(i,l)=TAUHID(i,klev-l+1,k)
210         enddo
211         enddo
212         write(str2,'(i2.2)') k
213       call histwrite_phy(nid_day,.false.,"thi"//str2,itau_w,t_tauhvd)
214       enddo      ! fin boucle NSPECI
215c --------------
216c ----- EXTINCTION BRUME
217       do k=7,NSPECV,10
218         do i=1,klon
219         do l=1,klev
220          if(l.ne.klev)
221     s     t_khvd(i,l)=TAUHVD(i,klev-l+1,k)
222     s                -TAUHVD(i,klev-l+1-1,k)
223          if(l.eq.klev)
224     s     t_khvd(i,l)=TAUHVD(i,klev-l+1,k)
225
226         t_khvd(i,l)=t_khvd(i,l)/(zzlev(i,l+1)-zzlev(i,l))
227         enddo
228         enddo
229         write(str2,'(i2.2)') k
230       call histwrite_phy(nid_day,.false.,"khv"//str2,itau_w,t_khvd)
231       enddo      ! fin boucle NSPECV
232
233       do k=8,NSPECI,10
234         do i=1,klon
235         do l=1,klev
236          if(l.ne.klev)
237     s     t_khvd(i,l)=TAUHID(i,klev-l+1,k)
238     s                -TAUHID(i,klev-l+1-1,k)
239          if(l.eq.klev)
240     s     t_khvd(i,l)=TAUHID(i,klev-l+1,k)
241
242         t_khvd(i,l)=t_khvd(i,l)/(zzlev(i,l+1)-zzlev(i,l))
243         enddo
244         enddo
245         write(str2,'(i2.2)') k
246       call histwrite_phy(nid_day,.false.,"khi"//str2,itau_w,t_khvd)
247       enddo      ! fin boucle NSPECI
248c --------------
249c ----- OPACITE GAZ
250       do k=7,NSPECV,10
251         do i=1,klon
252         do l=1,klev
253           t_tauhvd(i,l)=TAUGVD(i,klev-l+1,k)
254         enddo
255         enddo
256         write(str2,'(i2.2)') k
257       call histwrite_phy(nid_day,.false.,"tgv"//str2,itau_w,t_tauhvd)
258       enddo      ! fin boucle NSPECV
259
260       do k=8,NSPECI,10
261         do i=1,klon
262         do l=1,klev
263           t_tauhvd(i,l)=TAUGID(i,klev-l+1,k)
264         enddo
265         enddo
266         write(str2,'(i2.2)') k
267       call histwrite_phy(nid_day,.false.,"tgi"//str2,itau_w,t_tauhvd)
268       enddo      ! fin boucle NSPECI
269c --------------
270c ----- EXTINCTION GAZ
271       do k=7,NSPECV,10
272         do i=1,klon
273         do l=1,klev
274          if(l.ne.klev)
275     s     t_khvd(i,l)=TAUGVD(i,klev-l+1,k)
276     s                -TAUGVD(i,klev-l+1-1,k)
277          if(l.eq.klev)
278     s     t_khvd(i,l)=TAUGVD(i,klev-l+1,k)
279
280         t_khvd(i,l)=t_khvd(i,l)/(zzlev(i,l+1)-zzlev(i,l))
281         enddo
282         enddo
283         write(str2,'(i2.2)') k
284       call histwrite_phy(nid_day,.false.,"kgv"//str2,itau_w,t_khvd)
285       enddo      ! fin boucle NSPECV
286
287       do k=8,NSPECI,10
288         do i=1,klon
289         do l=1,klev
290          if(l.ne.klev)
291     s     t_khvd(i,l)=TAUGID(i,klev-l+1,k)
292     s                -TAUGID(i,klev-l+1-1,k)
293
294          if(l.eq.klev)
295     s     t_khvd(i,l)=TAUGID(i,klev-l+1,k)
296
297         t_khvd(i,l)=t_khvd(i,l)/(zzlev(i,l+1)-zzlev(i,l))
298         enddo
299         enddo
300         write(str2,'(i2.2)') k
301       call histwrite_phy(nid_day,.false.,"kgi"//str2,itau_w,t_khvd)
302       enddo      ! fin boucle NSPECI
303
304c --------------
305         if (clouds.eq.1) then
306c --------------
307c ----- OPACITE NUAGES (ATTENTION PROXY)
308         call histwrite_phy(nid_day,.false.,"tcld",itau_w,occcld)
309c --------------
310c ----- EXTINCTION NUAGES (ATTENTION PROXY)
311           do i=1,klon
312             t_kcld(i,klev)=occcld(i,klev)
313     .       /(zzlev(i,klev+1)-zzlev(i,klev))
314             do j=klev-1,1,-1
315               t_kcld(i,j)=(occcld(i,j)-occcld(i,j+1))
316     .         /(zzlev(i,j+1)-zzlev(i,j))
317             enddo
318           enddo
319         call histwrite_phy(nid_day,.false.,"kcld",itau_w,t_kcld)
320c --------------
321        endif 
322c --------------
323
324      ENDIF !lev_histday.GE.3
325
326c-------------------------------------------------------
327      IF(lev_histday.GE.4) THEN
328
329      call histwrite_phy(nid_day,.false.,"dtdyn",itau_w,d_t_dyn)
330      call histwrite_phy(nid_day,.false.,"dtphy",itau_w,d_t)
331c K/s
332      call histwrite_phy(nid_day,.false.,"dtvdf",itau_w,d_t_vdf)
333c K/s
334      call histwrite_phy(nid_day,.false.,"dtajs",itau_w,d_t_ajs)
335c K/s
336      call histwrite_phy(nid_day,.false.,"dtswr",itau_w,heat)
337c K/s
338      call histwrite_phy(nid_day,.false.,"dtlwr",itau_w,-1.*cool)
339c K/s     
340c      call histwrite_phy(nid_day,.false.,"dtec",itau_w,d_t_ec)
341
342      ENDIF !lev_histday.GE.4
343
344c-------------------------------------------------------
345      IF(lev_histday.GE.5) THEN
346
347c      call histwrite_phy(nid_day,.false.,"taux",itau_w,fluxu)
348c      call histwrite_phy(nid_day,.false.,"tauy",itau_w,fluxv)
349c      call histwrite_phy(nid_day,.false.,"cdrm",itau_w,cdragm)
350c      call histwrite_phy(nid_day,.false.,"cdrh",itau_w,cdragh)
351
352      ENDIF !lev_histday.GE.5
353c-------------------------------------------------------
354
355      if (ok_sync) then
356        call histsync(nid_day)
357      endif
358
359      ENDIF
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